H Enrichment Factors of Aerobic Bacterial ... - ACS Publications

Environ. Sci. Technol. 2007, 41, 2036-2043

Variations in 13C/12C and D/H Enrichment Factors of Aerobic Bacterial Fuel Oxygenate Degradation MO Å N I C A R O S E L L , † D A M I AÅ B A R C E L O Ä ,† THORE ROHWERDER,‡ UTA BREUER,§ MATTHIAS GEHRE,⊥ AND H A N S H E R M A N N R I C H N O W * ,⊥ Department of Environmental Chemistry, IIQAB-CSIC. Jordi Girona 18-26, 08034 Barcelona, Catalonia, Spain; Aquatic Biotechnology, Biofilm Center, University Duisburg-Essen, Geibelstr. 41, 47057 Duisburg, Germany; Department of Environmental Microbiology, Helmholtz Centre for Environmental Research - UFZ. Permoserstrasse 15, 04318 Leipzig, Germany; Department of Isotope Biogeochemistry; Helmholtz Centre for Environmental Research - UFZ. Permoserstrasse 15, 04318 Leipzig, Germany

Reliable compound-specific isotope enrichment factors are needed for a quantitative assessment of in situ biodegradation in contaminated groundwater. To obtain information on the variability on carbon and hydrogen enrichment factors (C, H) the isotope fractionation of methyl tertiary (tert-) butyl ether (MTBE) and ethyl tertbutyl ether (ETBE) upon aerobic degradation was studied with different bacterial isolates. Methylibium sp. R8 showed a carbon and hydrogen isotope enrichment upon MTBE degradation of -2.4 ( 0.1 and -42 ( 4‰, respectively, which is in the range of previous studies with pure cultures (Methylibium petroleiphilum PM1) as well as mixed consortia. In contrast, C of the β-proteobacterium L108 (-0.48 ( 0.05‰) and Rhodococcus ruber IFP 2001 (-0.28 ( 0.06‰) was much lower and hydrogen isotope fractionation was negligible (H e -0.2‰). The varying isotope fractionation pattern indicates that MTBE is degraded by different mechanisms by the strains R8 and PM1 compared to L108 and IFP 2001. The carbon and hydrogen isotope fractionation of ETBE by L108 (C ) -0.68 ( 0.06‰ and H ) -14 ( 2‰) and IFP 2001 (C ) -0.8 ( 0.1‰ and H ) -11 ( 4‰) was very similar and seemed slightly higher than the fractionation observed upon MTBE degradation by the same strains. The low carbon and hydrogen enrichment factors observed during MTBE and ETBE degradation by L108 and IFP 2001 suggest a hydrolysis-like reaction type of the ether bond cleavage compared to oxidation of the alkyl group as suggested for the strains PM1 and R8. The variability of carbon and hydrogen enrichment factors should be taken into account when interpreting isotope pattern of fuel oxygenates with respect to biodegradation in contamination plumes. * Corresponding author phone: +49-341-235-2810; fax: +49-341235-2552; e-mail: [email protected]. † IIQAB-CSIC. ‡ University Duisburg-Essen. § Department of Environmental Microbiology, Helmholtz Centre for Environmental ResearchsUFZ. ⊥ Department of Isotope Biogeochemistry; Helmholtz Centre for Environmental ResearchsUFZ. 2036

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Introduction Since the 1970s, fuel oxygenates (commonly ethers and alcohols) were used as octane enhancers. These compounds promote cleaner combustion and reduce vehicle air emissions. Methyl tertiary (tert-) butyl ether (MTBE) is by far the most commonly used oxygenate. Worldwide, about 20 Mt of MTBE are manufactured and used each year (60% in the U.S. and 15% in Europe), which puts it into the category of high production volume chemicals (1). As a result of this extensive use, and due to its high water solubility, considerable mobility and slow degradation rates, MTBE has become one of the most frequently detected volatile organic compounds in groundwater (2). Therefore, an increasing demand for the protection of drinking water resources can be assumed because odor and taste thresholds for MTBE are low, and it is a possible carcinogen (3, 4). Today, MTBE is substituted by ethyl tert-butyl ether (ETBE) in Europe due to tax incentives for the application of biomass-derived ethanol, which is synthesized to produce the ethyl group of ETBE (5). Thus, the production and consumption of ETBE will increase, and it is expected that ETBE will be one of the emerging fuelderived contaminants in Europe in the future. Groundwater sites heavily contaminated with fuel oxygenates have been identified in many countries (5-8) and natural attenuation is currently discussed as a management option (9, 10). In aquifers, in situ biodegradation is the only sustainable sink of MTBE and ETBE. One strategy to elucidate in situ biodegradation may be the analysis of metabolites; however, the mere presence of the intermediate tert-butyl alcohol (TBA) is inappropriate for providing evidence for natural attenuation of fuel oxygenates in many cases because it is a component of the original gasoline (11) or because it can originate from other industrial processes (12). During the past decade, laboratory degradation studies showed the potential of microbial communities to degrade fuel oxygenates under oxic and anoxic conditions (13). Aerobic bacterial strains capable of productive degradation of MTBE are, e.g., Methylibium petroleiphilum PM1 (14) and the β-proteobacterium strain L108 (15). In addition, growth on ETBE has been demonstrated with several aerobic strains such as strain L108 and Rhodococcus ruber IFP 2001 (16). The latter strain is not capable of growing on MTBE and shows only an incomplete degradation of ether oxygenates resulting in TBA accumulation. While the anaerobic pathway is practically unexplored there is general agreement that the initial step of the aerobic pathway is a hydroxylation reaction resulting in the cleavage of the ether bond. In case of R. ruber IFP 2001, the responsible ETBE monooxygenase has been identified (17, 18). Further aerobic degradation may proceed via tert-butyl formate (TBF) and TBA (19). The analysis of metabolites can be useful to characterize degradation pathways; however, quantitative information on the in situ degradation is difficult to obtain. Therefore, approaches are urgently needed to monitor the in situ biodegradation of fuel oxygenates in polluted groundwater tables. Recently, compound-specific stable isotope analysis (CSIA) has become a promising tool for evaluating in situ MTBE degradation (20, 21). CSIA makes use of kinetic isotope fractionation processes upon biodegradation leading to an enrichment of heavy isotopes (13C and 2H) in the residual fraction. For quantitative assessment of in situ degradation the compound specific isotope fractionation factor (R) is needed (22, 23) which is obtained in controlled laboratory studies. Knowledge of the variability of R is required to evaluate the uncertainty of quantitative 10.1021/es0616175 CCC: $37.00

 2007 American Chemical Society Published on Web 02/03/2007

field work. Moreover, the biochemical reaction may be characterized by the isotope fractionation pattern (24), which may allow identification of the degradation pathway in the field (20, 21, 25). This characterization relies on variations of isotope fractionation pattern correlating to particular microbial degradation mechanisms. MTBE carbon and hydrogen isotope fractionation has been found under oxic (26, 27) and anoxic conditions (20, 21, 25, 28, 29). Carbon enrichment factors for aerobic MTBE degradation were determined only from one pure culture, strain PM1, and two enrichment cultures (26, 27), and a limited number of experiments for stable hydrogen isotope fractionation are documented (27). Isotope fractionation studies of other ether oxygenates such as tert-amyl methyl ether (TAME) or ETBE are scarce (28). Therefore, a more systematic study on hydrogen and carbon isotope fractionation under defined conditions is needed for evaluating the CSIA concept for characterizing and assessing in situ biodegradation of fuel oxygenates. The objective of this study is to investigate the variability of isotope fractionation upon aerobic biodegradation of fuel oxygenates (MTBE and ETBE). We examined the carbon and hydrogen enrichment factors (C, H) obtained by strains L108, R. ruber IFP 2001, and the newly isolated strain Methylibium sp. R8 under controlled laboratory conditions. The results were interpreted with respect to the variability of isotope fractionation to investigate degradation pathways and to quantify the in situ biodegradation.

Experimental Section Chemicals. All chemicals were purchased from Sigma-Aldrich Chemie (Munich, Germany) at the highest purity available unless stated elsewhere. MTBE was obtained from Merck in p. a. quality and ETBE (purum, g97.0%, GC) purchased from Fluka (Buchs, Switzerland). Bacterial Strains and Cultivation Conditions. Strain L108 belongs to β-Proteobacteria and was isolated from MTBEcontaminated groundwater (Leuna, Germany) (15) and showed a 95.6% identity of the 16S rRNA gene to M. petroleiphilum PM1 (Supporting Information). Methylibium sp. R8 was isolated from a MTBE-degrading enrichment culture provided by E. Arvin (DTU, Denmark). The strains L108 and R8 were aerobically cultured in a mineral salt medium on MTBE as sole source of carbon and energy (15). Strain R8 did not grow productively on ETBE. Rhodococcus ruber IFP 2001 was provided by F. FayolleGuichard (IFP, France) and was cultured in the abovedescribed mineral salt medium on ETBE. For isotope fractionation experiments, the microorganisms were aerobically incubated with 50 mL mineral salt solution in 240-mL serum bottles. MTBE or ETBE was added to a final concentration of 100-500 mg/L. Two-percent inoculum (v/v) was added and the cultures were incubated on a rotary shaker at 30 °C. A negative control without inoculum was incubated under identical conditions in each series (see the Supporting Information for further details). Experiments with Resting Cells. Strains L108 and IFP 2001 were used for isotope fractionation with resting cells. Bacteria were grown on either MTBE (strain L108) or ETBE (both strains) and harvested by centrifugation. Cells were washed with mineral salt solution and suspended at a concentration of 1-2 g/L (biomass dry weight). 50 mL of this cell suspension was supplemented with MTBE or ETBE at 100-200 mg/L and incubated on a rotary shaker at 30 °C. Over an 8-h period up to 99.9% of the substrate was decomposed. In cometabolic degradation experiments with MTBE and strain IFP 2001, glucose at a final concentration of 350 mg/L was added as a cosubstrate (see the Supporting information).

Analytical Methods. Specific cultivation conditions are detailed in the Supporting Information. For sampling, aliquots (2.5 mL) of the medium were removed with a syringe. From this sample, a 1 mL subsample of each was transferred into 10-mL headspace vials (i) for headspace GC analysis of the ETBE, MTBE, and TBA concentration (15) and (ii) for the stable isotope analysis. In both cases, bacterial activity was stopped by mixing the sample with the same volume of aqueous saturated NaCl solution. Samples not immediately analyzed were stored at -20 °C until further processing. External five-point linear regression curves were employed for quantitative GC analysis. Reproducibility of concentration values was ( 5% and detection limits were 250, 10, and 20 µg/L for TBA, MTBE, and ETBE, respectively. Stable isotope composition was determined using a gaschromatography-combustion-isotope ratio monitoringmass spectrometry system (GC-C-IRM-MS). The system consisted of a GC (6890 series; Agilent Technology) coupled with a combustion or high-temperature pyrolysis interface (GC-combustion III or GC/C-III/TC; ThermoFinnigan, Bremen, Germany) to a MAT 252 IRMS for the carbon and to a MAT 253 IRMS for hydrogen analysis (both from ThermoFinnigan, Bremen, Germany). Headspace samples were injected in split or splitless mode. The method had detection limits for MTBE and ETBE of approximately 3 mg/L for carbon and 8 mg/L for hydrogen. The error associated to the system (accuracy and reproducibility) was commonly about ( 0.5‰ for carbon and ( 4‰ for hydrogen (see the Supporting Information for further details). The standard deviation (SD) of at least three individual measurements was reported. Stable Isotope Calculations and Definitions. The carbon and hydrogen isotopic compositions (R) are reported as delta notation (δ13C and δ2H) in parts per thousand (‰) relative to an international standard; Vienna Pee Dee Belemnite standard (V-PDB) and Vienna Standard Mean Ocean Water (V-SMOW), respectively (30). δ values were calculated as follows:

δ[(‰)] )

(

)

Rsample - 1 × 1000 Rreference

(1)

where Rsample and Rreference are the ratios of the heavy isotope to the light isotope (13C/12C or D/H) in the sample and an international standard, respectively. Calculation of the isotopic fractionation factor (R) was based on the Rayleigh equation (31) simplified for a closed system (32):

ln

() ( ) () Rt Ct 1 ) - 1 × ln R0 R C0

(2)

where R is the isotope ratio, C is the concentration, and the index (0 and t) describes the incubation time at the beginning (0) and during the reaction time of experiment (t). When ln(Rt/R0) versus ln(Ct/C0) was plotted, the isotopic enrichment factor () within the 95% confidence interval (95% CI) could be determined from the slope (b) of the linear regression of each data set, with b ) (1/R) - 1 and  ) 1000 × b. The experiments were repeated for the various strains until representative biodegradation points were reached.

Results and Discussion Concentration Profiles. The time course of MTBE and ETBE degradation of the strain L108 under oxic conditions was studied (see Figure S1 in the Supporting Information). With initial MTBE concentrations between 200 and 500 mg/L, up to 15 days were necessary for a degradation of 99.9%. The 70-250 mg/L concentration of ETBE was degraded within the same time period to a similar extent. ETBE was not degraded by strain R8 and for similar initial MTBE concenVOL. 41, NO. 6, 2007 / ENVIRONMENTAL SCIENCE & TECHNOLOGY

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FIGURE 1. Double logarithmic plot according to the Rayleigh equation of the isotopic composition versus the residual concentration of substances (A) carbon isotope fractionation of MTBE, (B) carbon isotope fractionation of ETBE, (C) hydrogen isotope fractionation of MTBE, and (D) hydrogen isotope fractionation of ETBE; by strain L108 (O), strain R8 (9), and strain IFP 2001 (2). The lines correspond to a linear regression model. trations, as in experiments with L108, approximately twice the time was required. In 26 days, this strain degraded about 500 mg/L to 99.9% (data not shown). Conversely, strain IFP 2001 (that only grew on ETBE) was found to be the most effective. In less than 5 days, 250 mg/L of ETBE were consumed. As indicated in previous studies, a concomitant accumulation of TBA was detected (16). During each experiment, MTBE and ETBE concentrations remained constant in negative controls. In addition, TBA was not detected under sterile conditions.

isotope fractionation observed for MTBE thus far. The C obtained in ETBE degradation experiments with strains L108 and IFP 2001 were nearly identical (-0.68 ( 0.06‰ and -0.8 ( 0.1‰, respectively) and quite similar to those obtained for MTBE. Moreover, ETBE degradation assay with L108 resting cells (experimental details are given in the Supporting Information) did not show significant differences in C value (-0.8 ( 0.1‰) in comparison to the fractionation in growing cultures. However, to our knowledge, no other values are available to date in the literature for comparison.

Carbon Isotopic Profiles. The initial δ13C for MTBE and ETBE (-29.4 ( 0.1‰ and -24.3 ( 0.1‰, respectively) were calculated as the average of three different samples at time zero, and these values remained constant in the negative controls during the whole period of incubation. In live cultures, δ13C of MTBE and ETBE increased as biodegradation proceeded (as shown in Figure S1, Supporting Information) for three batch experiments with strain L108, indicating the enrichment of 13C in the residual compound fraction. The investigation of ETBE fractionation by strain R8 was not possible, since the strain was not able to degrade ETBE.

Hydrogen Isotopic Profiles. The initial hydrogen isotope composition of MTBE and ETBE was -177 ( 2 ‰ and -223 ( 3‰, respectively, and remained stable in the negative control over 14 days of incubation. The hydrogen isotope fractionation of strain R8 was much stronger (H ) -42‰) than the carbon isotope fractionation (C ) -2.4‰) upon biodegradation as expected. Surprisingly, the two strains L108 and IFP 2001 did not exhibit almost any detectable hydrogen isotope fractionation upon MTBE degradation. The calculated enrichment factor was almost below -0.2‰ with a trend to inverse isotope fractionation. Although the uncertainty within the 95% CI was rather high, the hydrogen enrichment factors were significantly lower than those of strain R8 or PM1 (Table 1). For example, in the experiment with strain L108, the average δ2H value after 82% of MTBE degradation was -180 ( 2‰ and similar to the negative control (Figure S1 A, Supporting Information). However, slight enrichment in δ2H as observed for carbon isotopes may not be detectable for hydrogen as a higher error is associated with the determination of hydrogen isotopes. The hydrogen isotope fractionation of R8 upon MTBE degradation (-42 ( 4‰) was in the same range within 95% CI as reported for PM1 ranging from -33 to -37‰ (5‰ (H) but even lower than reported for a mixed consortium (up to -66‰) (27) (Table 1). In contrast to MTBE, in all live cultures an enrichment in δ2H upon ETBE degradation could be detected (Figure 1 C and D).

The carbon enrichment factors (C) were calculated with the Rayleigh equation (Figure 1, A and B). Results for all strains and substrates are summarized in Table 1. The relatively good correlation between concentration and isotope composition with correlation factors (R2) between 0.81 and 0.98 suggested that carbon isotope fractionation during aerobic MTBE and ETBE degradation can be modeled by the Rayleigh equation. The degradation experiments with L108 and IFP 2001 gave a similar C between -0.48 ( 0.05‰ and -0.28 ( 0.06‰, respectively. In contrast, strain R8 showed 1 order of magnitude higher C of -2.4 ( 0.1‰, which are very similar to values obtained with PM1 ranging between -2.0 and -2.4‰ (C) reported by Gray et al. (27). Although mixed cultures showed a slightly lower C between -1.5 and -1.97‰ (26, 27), the factors obtained in experiments with strains L108 and IFP 2001 showed the lowest 2038

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TABLE 1. Comparison of Isotopic Enrichment Factors (E) with 95% Confidence Intervals (95% CI) and Apparent Kinetic Isotope Effects (AKIE) for Aerobic Biodegradation of MTBE and ETBEa MTBE culture

ECbulk [‰]

95% CI [‰]

ECreactive position (n/x ) 5/1)

AKIEC

enrichment culture -1.52 to -1.97 0.06 -7.6 to -9.85 1.008 to 38 (Borden aquifer) 1.010 VAFB -1.5 to -1.8 0.1 -7.5 to -9 1.008 to 55 mixed consortium 1.009 strain PM1 -2.0 to -2.4 0.1 to 0.3 -10 to -12 1.010 to 39 1.012 strain L108 -0.48 0.05 -2.4 1.002 34 strain IFP2001 (resting cells)

-0.28

0.06

-1.4

1.001

strain R8

-2.4

0.1

-11.8

1.012

95% CI EHreactive position [‰] (n/x ) 12/3)

EHbulk [‰]

Nb

AKIEH

Nb reference 26

not applicable -29 to -66

3 to 4 -116 to -264 4 to 5 -132 to -148 8

-33 to -37

no enrichment (-0.2) 27 no enrichment (+5) 40 -42

1.53 to 24 27 4.81 1.66 to 26 27 1.80 29 this work

17 4

24 this work -169

2.03

36 this work

ETBE culture strain L108 strain L108 (resting cells) strain IFP2001 strain R8

95% CI [‰]

ECreactive position (n/x ) 6/1)

AKIEC

Nb

-0.68 -0.8

0.06 0.1

-4.06 -4.6

1.004 1.005

51 10

-0.8 not applicable

0.1

-4.4

1.004

16

ECbulk [‰]

95% CI [‰]

EHreactive position (n/x ) 14/2)

AKIEH

Nb

-14 -11

2 3

-98 -77

1.24 1.18

41 13

this work this work

-11 not applicable

4

-77

1.18

19

this work this work

EHbulk [‰ ]

a The  reactive position values were obtained by the approximated equation  reactive position ≈ n/x × bulk where n is the number of atoms of the element considered that are present in the molecule and x of them are located at the reactive site. b N ) number of samples

The hydrogen enrichment factor (H) of strain L108 and IFP 2001 was between -11 and -14‰. In the experiment with resting cells of strain L108, the H (-11 (3‰) was not significantly different (within the range given as 95% CI) compared to growing cells (-14 (2‰). The hydrogen and carbon ETBE fractionation by growing cells of the strains L108 and IFP 2001 were positively correlated similar to the experiment with resting cells of strain IFP 2001. Nearly identical hydrogen as well as carbon isotope enrichment factors were obtained, indicating that no significant difference in isotope fractionation were detected with growing or resting cells, respectively. The times of substrate consumption changed from 2 weeks in growth experiments to some hours in resting cell experiments and indicate that the overall kinetics of degradation as well as the amount of biomass did not affect the isotope fractionation in this case. Therefore, degradation assays with resting cells may be an alternative in place of long incubation experiments which are timeconsuming and often do not allow the progress in biodegradation to be monitored steadily. Kinetic Isotope Effects (KIE). Recently kinetic carbon and hydrogen isotope fractionation patterns were used to gain information on the biochemical mechanism governing in situ biodegradation. The direct comparison of isotopic enrichment factors (bulk) obtained for different compounds requires normalization to the reactive position since only the atom where the reaction takes place is involved in the isotope fractionation process and other parts of the molecule remains unaltered (24). Starting from basic rate laws, a quite general derivation of the Rayleigh equation was obtained, taking into account the effects of (i) nonreacting positions and (ii) intramolecular competition and leading to positionspecific apparent kinetic isotope effects (KIE) values rather than bulk enrichment factors (bulk). The factor describing the fractionation at the reactive position (reactive position) and the apparent KIE of the reaction (AKIE) were calculated according to Elsner et al. (24). Since intramolecular competition was considered negligible during oxidation process (z ) x), the approximated eqs 3 and 4 were

applied to the oxidation of methoxy and ethoxy group of MTBE and ETBE, respectively, as follows:

reactive position ≈ AKIEE )

n × bulk x

(3)

1 1 ≈ n 1 + (n‚bulk/1000) 1 + z‚ bulk/1000 x

(

)

(4)

where n is the number of the atoms of the element considered of which x is the atom located at the reactive site and z the number of atoms which are involved in the intramolecular isotopic competition. Hence, for carbon fractionation, one of five atoms of MTBE is located at the reacting position, whereas one of six atoms of ETBE. For correcting the hydrogen fractionation of MTBE, we assume that three out of 12 atoms are bound to the methoxy group and are involved in intramolecular isotopic competition (z), whereas for ETBE, two out of 14 atoms are bound to the ethoxy group in the reactive position (z). Table 1 shows the corrected values in comparison with values available in the literature. Creactive position and Hreactive position for strains PM1 and R8 are similar suggesting a similar biochemical mechanism in the degradation of MTBE. PM1 and R8 are close relatives, and therefore, their phylogenetic relationship is reflected by the fractionation pattern (see the Supporting Information). In contrast, strains L108 and IFP 2001 show a significantly lower carbon fractionation (nearly 1 order of magnitude) and almost no hydrogen fractionation indicating a different biochemical degradation mechanism. In the latter case, carbon and hydrogen isotope composition is not correlated indicating that, in contrast to carbon, a cleavage of a hydrogen bond is not a limiting step in the overall reaction kinetics. In previous studies, the uptake of substrate has been shown to affect the isotope composition (33-35); however, in this case, the transport limitation or diffusion through the microbial cell membrane should affect both elements in a similar way. This is not the case because VOL. 41, NO. 6, 2007 / ENVIRONMENTAL SCIENCE & TECHNOLOGY

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a slight carbon but no hydrogen isotope fractionation was observed. In addition, the gram-negative strains R8, PM1, and L108 have different cell wall structures than the grampositive IFP 2001, which could affect the isotope fractionation. However, possible differences in uptake of substrates cannot be employed here to explain the isotope fractionation pattern because it is unlikely that kinetic limitations due to uptake can selectively affect carbon or hydrogen isotope fractionation. Thus, it is more likely that a different biochemical mechanism is responsible for the observed difference in the isotope fractionation. Creactive position of MTBE by L108 and IFP 2001 was more than 40% lower than for ETBE indicating different pathways may be at work as well. This assumption is supported by the fact that for ETBE hydrogen bond cleavage is involved in a rate-limiting step of the reaction but not for MTBE. The biodegradation mechanisms can significantly influence the isotope fractionation pattern (35-37). In summary, the fractionation pattern gives first indications on the biochemical mechanism which takes place in the initial steps of the transformation reactions. A further method for interpreting isotope fractionation is to calculate the AKIE (eq 4). The AKIE values for breaking hydrogen, carbon, or oxygen bonds can be compared to the possible maximal theoretical fractionation called Streitwieser Semiclassical Limits (38). The cleavage of the ether bond leading to TBA as a product may occur via different mechanisms for example initiated by (I) the cleavage of the C-H bond by oxidation, (II) an acidic hydrolysis (SN1), or (III) hydrolysis by (enzymatic) nucleophilic attack (SN2), which may be distinguished by their fractionation effects on hydrogen and carbon (24). Experimental KIE values for chemical reactions are often 50% lower compared to the theoretical values which have to be considered for interpretation (24). In the case of MTBE degradation by strains L108 and IFP 2001, the hydrogen isotope fractionation was very low (